Ch1-Env Sci Sustain(1).pdf

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CHAPTER 1

Environmental Science and
Sustainability: What’s the Big
Idea?

Copyright © 2023 W. W. Norton & Company, Inc.
Chapter 1 Outline
1.1 What Is the Environment, and What Is an Ecosystem?
1.2 What Is Sustainability?
1.3 What Is Environmental Justice?
1.4 What Is Science?
1.5 What Are Challenges to Good Science?
1.6 What Shapes Our Decisions on the Environment?
 Chapter Objectives: This chapter will help you…
describe the range of ways in which humans affect the environment.

summarize how the scientific method works.

describe the various methods of observation and testing involved in
scientific inquiry.

identify ways in which values influence our individual and collective
responses to environmental issues.
 1.1 What Is the Environment, and What Is an Ecosystem? (1 of 2)
Environment is a collection of systems including all living and nonliving things on
Earth that sustain all life.
A system is made up of interacting components that produce patterns of behavior over
time, like a household.
A car is made up of many components. Each by itself will not get you from one place
to another
Only when all parts put together you can use the car to get around
This is called an emergent property of the whole system.
The environment is made up of many natural systems called ecosystems, like a coral
reef.
A coral reef is an ecosystem made up of marine organisms and nonliving factors like
sunlight and minerals.
The root of the prefix eco- in the words ecosystem, ecology, and economics is the
Greek word oikos, which means household
 What Is the Environment, and What Is an Ecosystem? (2 of 2)
Ecosystem has many interacting parts such as a forest.
A forest ecosystem has many interacting parts such as
organisms that live both above and below the ground.
Humans use ecosystem services or Earth’s natural
resources, such as oxygen, water, and energy, to survive.
Environments cycle nutrients, break down waste, and
provide climates conducive to our survival.
Indigenous knowledge such as the idea that “if you take
care of the environment, the environment takes care of
you” helps us understand and appreciate these
connections.
 Where Do Humans Fit in the Environment? What’s Our Impact?

With more than 8 billion people on Earth,
humans dominate the planet.

We call the current epoch of Earth’s history
the Anthropocene (the prefix anthro-
means “human”) because of realizations
about our impacts.

Even from space, we can see human impact
as cities light up the night.
Before urban sprawl and subsequent habitat
loss, the land was composed of natural systems
like forests and wetlands.
Human Environmental Impacts Are NOT Confined to Land

Terrestrial habitat loss and human impact on oceans

One way that human environmental effects are This map shows that ALL areas of the oceans
becoming apparent is through tracking human have also experienced at least medium impact
activities, such as urbanization, agriculture, and due to human effects—such as pollution and the
forestry, that have transformed the landscape— harvest of sea creatures-on marine ecosystems.
causing the loss of habitat for other species.
AT A GLANCE Major Human Actions Affecting the Environment
Take-Home Message
The environment is made up of living and nonliving things that sustain life
on Earth.
Humans rely on natural resources for everything, which is having a large
negative impact on Earth’s natural resources
 1.2 What Is Sustainability? (1 of 4)
The ways humans make their living in today’s
world affect all life.

Historically, native peoples protected natural
populations such as Pacific salmon, which are
integral to their cultures and diets.

Managing natural resources that allow them to be
used but not destroyed for future generations
reflects a philosophy of sustainability.
Sustainability means managing natural resources in ways that do
not diminish or degrade Earth’s ability to provide them in the
future. Using less-polluting forms of energy (such as solar power) and
harvesting fish at levels that allow for stable populations in the future
are two examples of sustainable practices.
What Is Sustainability? (2 of 4)
Sustainability is the management of natural resources in ways that do
not diminish or degrades Earth’s ability to provide them in the future.
On a planetary scale, sustainable practices maintain natural processes
such as nutrient cycling and climate systems.
Creating specific goals that lead to sustainable systems requires making
decisions that help us meet those goals.
Addressing questions such as the following may allow us to meet our
goals:
What kind of uses and benefits are we trying to sustain?
What sorts of factors affect the continuation of those uses and benefits?
At what rate should we allow, for ex., trees to be cut, or fish harvested?
How much forest, or fish stock, should we leave standing?
How should we manage other uses of the forest or fisheries?
 What Is Sustainability? (3 of 4)

In 1987, the United Nations (UN) defined the term
sustainable development as “development that meets
the needs of the present without compromising the
ability of future generations to meet their own needs.”
The UN report considered the environmental effects of
human actions as well as the economic and social
effects, known as the 3Es (environment, economy,
and equity) or 3Ps (planet, profit, and people).
In 2016, the UN released 17 sustainable development
goals (SDGs) that cover the 3Es on a global scale.
For each of the 17 goals, specific indicators were
identified to measure progress over time; for
example, marine pollution levels are used as
indicators to track progress with sustaining ocean
ecosystems
What Is Sustainability? (4 of 4)

One of the sustainable development
goals is combating climate change,
which are the long-term changes in
climate conditions such as
temperature and precipitation.
Scientists conduct studies and
communicate important results that
help us understand current
environmental problems and their
drivers.
 Ecological Resilience
A healthy ecosystem can usually withstand
natural and human-caused events.
Wildfires, hurricanes, overfishing,
deforestation, etc.
Sustainable ecosystems display ecological
resilience
How well systems recover & maintain the
overall functionality even after disruption.
Resistance: avoiding change to disturbance.
It is important to understand the processes Recovery: returning to the original state after
that contribute to ecosystem resilience disturbance.
For ex., coastal cities, such as New York after Resilience: it is about both resisting and
Superstorm Sandy, are now preserving recovering from disturbances, and maintaining
shoreline ecosystems that will help resist the overall health even if the system undergoes
some level of change.
future storm damage.
Take-Home Message

Sustainability is the management of natural resources in ways that
do not diminish or degrades Earth’s ability to provide them in the
future.
It aims to meet the needs of the present without compromising the
needs of future generations
The ecological resilience to recover from damage is a key factor in
sustainability
 1.4 What Is Science? (1 of 2)
Why are we talking about science in
sustainability course?
Developing sustainable goals
requires understanding ecosystems
and science, which is our way of
asking and answering questions,
and testing ideas about the natural
world through evidence-gathering.
Science involves inquiry and is an
ongoing process that uses steps
called the scientific method.
 What Is Science? (2 of 2)
Following observation of a problem or natural
phenomenon, scientists formulate a hypothesis, a
proposed explanation or answer to a scientific question.
Observation of a problem sometimes occurs while
examining a different problem (accidental discovery).
For example, in the 1950s, Caltech geochemist Clair
Patterson “accidentally” discovered the problem of lead
in urban areas from automobiles while he was studying
lead levels in rocks.
His research resulted in the banning of Lead additives to
gasoline in 1986.
Ways of Observing and Testing (1 of 2)
The hypothesis is a statement that attempts to explain a phenomenon or
answer a scientific question.
The hypothesis is tested in a controlled experiment.
In a controlled experiment, researchers compare two situations, one
situation with one aspect intentionally manipulated and another situation
unmanipulated (the control), to determine if that singular aspect changes
the results.
Experiments are designed with predicted results that provide evidence that
either supports or refutes a hypothesis.
In order for a scientific discovery to be accepted, it must be methodically
documented, shared, and demonstrated so that other scientists can replicate
the investigation in a way that the discovery is reproducible and open to the
public.
Example in the next slide.
 Ways of Observing and Testing (2 of 2)
Scientists had two hypotheses about what caused coral
bleaching and developed controlled experiments to test
them. Their hypotheses were as follows:
1. Increasing ocean temperature is the environmental
stressor causing coral bleaching.
Comparing tanks with water at high temperature to
control tanks (normal ocean temperature) showed
that higher temperature causes bleaching

2. Ocean acidity due to increase of atmospheric CO2
concentrations causes coral bleaching.
Comparing tanks with water of higher acidity than
normal ocean acidity showed that higher acidity
causes bleaching
 Models

To understand natural phenomena, a
simplified representation of a complex
process, called a model, is often created.
Models assemble data and attempt to
simulate what actually happens or what
will happen.
Weather models run globally and are
constantly revised when new data are
provided.
1.5 What Are Challenges to Good Science?
Evaluating sources of information is important.

Some sources make claims that lack integrity and do not properly use the
scientific method.

Purposely deceiving people by presenting findings that are false is called
fraud.

Other claims may not intend to deceive but have not used the scientific
method and are called pseudoscience.
Bias and Misinformation
All humans are prone to biases—unreasonable
weighting of source information, inclinations, and/or
prejudices—that lead to errors and
misunderstandings.

Sometimes, our understanding of the natural world is
a product of misinformation, which is false or
incorrect information that may be spread
intentionally or unintentionally.
 Take-Home Message
Science asks and answers questions about the natural world by testing
hypotheses against evidence from the natural word.

The scientific method uses observations to test and sort through
alternative explanations.

Models assemble observations to simulate what happens in the world,
helping to show interactions of different factors
 1.6 What Shapes Our Decisions on the Environment?

Sustainability requires more than scientific
inquiry.
Science alone cannot determine what should be
done about a particular environmental issue.
A solution involves values, which reflect our
understanding of how we want things to be or
what we desire, aim for, or demand.

Should I bike to school or ride a car?
Should I catch 2 or 5 fish?
Should I wear clothes that are made with natural
coloring or not?
 Trade-Offs and Incentives
When we consider the pros and cons, or benefits and costs, of alternative courses of action,
we are considering trade-offs.
Public agencies and businesses may use communication strategies that intend to raise our
cost-and-benefit awareness, which may alter our decisions based on our cost-benefit
analysis.
Here, science tells you that using mass transportation is more eco-friendly
However, science can’t tell you to choose riding a bus and not using your own car
Likewise, science can’t tell you walk or use a scooter rather than ride the bus to go
around campus
Other strategies may include positive or negative incentives meant to influence our choices.
Using the university bus for rides between campus and home is free-positive
Add expensive parking meters, and farther parking lots-negative
Making Sense of Our Environmental Effects
Our individual choices and actions add up to significant environmental
effects.
To measure our personal impact on the environment, ecological footprint
analysis translates our actions into an estimate of total natural resources
needed to support our current lifestyles.
Carbon footprints can also be measured to estimate levels of greenhouse
gas emissions that contribute to global warming.
Global footprints can be measured in standard units of land called global
hectares (gha), which measure how much land it takes to support individual
or national lifestyles.
The United States, China, and India are the countries with the largest
ecological footprints.
Ecological Footprints of Different Nations

https://www.footprintnetwork.
org/resources/footprint-
calculator/
Groups and Organizations to promote sustainability
We all gain influence when we collaborate within social networks.
On college campuses, environmental organizations can link together
networks of individuals with common goals.
There is power in numbers, as organizations can often accomplish
more than individuals.
Take-Home Message
What we value often determines any actions taken as a result of
scientific inquiry, especially when it comes to decisions about the
environment.
Values reflect what we desire or demand.
They are what we use to assign relative worth, merit, or importance
to different things
One might think I is better to keep a forest for enjoyment and
ecological value; another may think it is better to cut the trees for
timber that we can use in construction
Question 1
An example of ecosystem services would include _______________.

A. agricultural fertilizers
B. energy companies
C. municipal wastewater treatment plants
D. wetlands that naturally purify water
E. sunlight
Question 1 Answer
An example of ecosystem services would include _______________.

A. agricultural fertilizers
B. energy companies
C. municipal wastewater treatment plants
D. wetlands that naturally purify water (Correct)
E. sunlight
Question 2
How would you describe the Anthropocene Epoch?

A. It is an era in Earth’s history when dinosaurs roamed Earth.
B. It is a time in Earth’s history when there were only sea-dwelling
organisms.
C. It is marked by conspicuous human effects on the planet and is
happening now.
D. It is a time in Earth’s history when all continents were connected in a
large landmass.
Question 2 Answer

How would you describe the Anthropocene Epoch?

A. It is an era in Earth’s history when dinosaurs roamed Earth.
B. It is a time in Earth’s history when there were only sea-dwelling
organisms.
C. It is marked by conspicuous human effects on the planet and is
happening now. (Correct)
D. It is a time in Earth’s history when all continents were connected in a
large landmass.
Question 3

Which of the following are the 3Es of sustainable development?

A. essential, entrepreneurial, and excessive
B. environment, economy, and equity
C. ephemeral, exclusive, and emerging
D. exhaustive, empowering, and expensive
Question 3 Answer

Which of the following are the 3Es of sustainable development?

A. essential, entrepreneurial, and excessive
B. environment, economy, and equity (Correct)
C. ephemeral, exclusive, and emerging
D. exhaustive, empowering, and expensive
Question 5

Which statement accurately describes the scientific method?

A. It is a formal process of inquiry designed to test problems and ideas.
B. Scientists never repeat the scientific process being investigated.
C. Observations of a scientific problem never happen by accident.
D. Scientists do not develop a hypothesis until the investigation is
completed.
E. The scientific hypothesis is always accepted at the end of the
investigation.
Question 5 Answer

Which statement accurately describes the scientific method?

A. It is a formal process of inquiry designed to test problems and
ideas.
B. Scientists never repeat the scientific process being investigated.
C. Observations of a scientific problem never happen by accident.
D. Scientists do not develop a hypothesis until the investigation is
completed.
E. The scientific hypothesis is always accepted at the end of the
investigation.